中文

RA-DCA: A Randomized Active-Set DCA for Directional Stationarity in Max-Structured DC Programs

最优化与控制 2026-05-25 v1 人工智能 数值分析 数值分析

摘要

We study nonsmooth difference-of-convex programs whose subtracted convex term is a finite maximum of smooth convex functions. In this setting, standard DCA iterations may converge to critical points that are not directionally stationary, whereas exact active-vertex screening can be expensive when active sets are large or combinatorial. We propose RA-DCA, a vertex-first randomized active-set DCA that projects active gradients onto sampled directions, checks a sampled vertex residual, and uses a small linear program only as a low-residual convex-combination fallback. The method preserves the descent structure of DCA and reduces the randomized screening layer to matrix multiplications. Under the stated regularity, numerical active-set consistency, and random-embedding assumptions, every accumulation point generated by the safeguarded method is directionally stationary with probability one. MATLAB experiments first test the theorem on degenerate max-affine, max-quadratic, and sparse support-function models, where the safeguard avoids nonstationary critical points and closely tracks a full active-vertex scan. Block top-k tests then show that the same screening idea remains useful when exact aggregate enumeration is combinatorial. Trimmed-regression, complementarity, and QUBO diagnostics separate cases where active-set selection helps from cases dominated by multistart search, the DC split, or other problem-specific features.

关键词

引用

@article{arxiv.2605.23550,
  title  = {RA-DCA: A Randomized Active-Set DCA for Directional Stationarity in Max-Structured DC Programs},
  author = {Yi-Shuai Niu},
  journal= {arXiv preprint arXiv:2605.23550},
  year   = {2026}
}

备注

40 pages, 7 figures